XC18V04PC44 [XILINX]
In-System Programmable Configuration PROMs; 在系统可编程配置PROM型号: | XC18V04PC44 |
厂家: | XILINX, INC |
描述: | In-System Programmable Configuration PROMs |
文件: | 总21页 (文件大小:227K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
0
XC18V00 Series In-System
Programmable Configuration
PROMs
R
0
0
DS026 (v4.0) June 11, 2003
Product Specification
•
Dual configuration modes
Features
-
-
Serial Slow/Fast configuration (up to 33 MHz)
Parallel (up to 264 Mb/s at 33 MHz)
•
In-system programmable 3.3V PROMs for
configuration of Xilinx FPGAs
-
-
Endurance of 20,000 program/erase cycles
•
•
•
•
5V tolerant I/O pins accept 5V, 3.3V and 2.5V signals
3.3V or 2.5V output capability
Program/erase over full commercial/industrial
voltage and temperature range (–40°C to +85°C)
Available in PC20, SO20, PC44, and VQ44 packages
•
•
•
•
IEEE Std 1149.1 boundary-scan (JTAG) support
Simple interface to the FPGA
Design support using the Xilinx Alliance and
Foundation series software packages.
Cascadable for storing longer or multiple bitstreams
Low-power advanced CMOS FLASH process
•
JTAG command initiation of standard FPGA
configuration
When the FPGA is in Master-SelectMAP mode, the FPGA
generates a configuration clock that drives the PROM.
When the FPGA is in Slave-Parallel or Slave-SelectMAP
Mode, an external oscillator generates the configuration
clock that drives the PROM and the FPGA. After CE and
OE are enabled, data is available on the PROMs DATA
(D0-D7) pins. New data is available a short access time
after each rising clock edge. The data is clocked into the
FPGA on the following rising edge of the CCLK. A free-run-
ning oscillator can be used in the Slave-Parallel or
Slave-SelecMAP modes.
Description
Xilinx introduces the XC18V00 series of in-system program-
mable configuration PROMs (Figure 1). Devices in this 3.3V
family include a 4-megabit, a 2-megabit, a 1-megabit, and a
512-kilobit PROM that provide an easy-to-use, cost-effec-
tive method for re-programming and storing Xilinx FPGA
configuration bitstreams.
When the FPGA is in Master Serial mode, it generates a
configuration clock that drives the PROM. A short access
time after CE and OE are enabled, data is available on the
Multiple devices can be concatenated by using the CEO
output to drive the CE input of the following device. The
clock inputs and the DATA outputs of all PROMs in this
chain are interconnected. All devices are compatible and
can be cascaded with other members of the family or with
the XC17V00 one-time programmable Serial PROM family.
PROM DATA (D0) pin that is connected to the FPGA D
IN
pin. New data is available a short access time after each ris-
ing clock edge. The FPGA generates the appropriate num-
ber of clock pulses to complete the configuration. When the
FPGA is in Slave Serial mode, the PROM and the FPGA
are clocked by an external clock.
CLK CE
OE/Reset
TCK
Data
Control
CEO
Serial
or
Parallel
Interface
TMS
TDI
and
JTAG
Interface
Memory
D0 DATA
Serial or Parallel Mode
Data
Address
TDO
7
D[1:7]
Parallel Interface
CF
DS026_01_090502
Figure 1: XC18V00 Series Block Diagram
©2003 Xilinx, Inc. All rights reserved. All Xilinx trademarks, registered trademarks, patents, and further disclaimers are as listed at http://www.xilinx.com/legal.htm. All other
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NOTICE OF DISCLAIMER: Xilinx is providing this design, code, or information "as is." By providing the design, code, or information as one possible implementation of this fea-
ture, application, or standard, Xilinx makes no representation that this implementation is free from any claims of infringement. You are responsible for obtaining any rights you
may require for your implementation. Xilinx expressly disclaims any warranty whatsoever with respect to the adequacy of the implementation, including but not limited to any war-
ranties or representations that this implementation is free from claims of infringement and any implied warranties of merchantability or fitness for a particular purpose.
DS026 (v4.0) June 11, 2003
www.xilinx.com
1
Product Specification
1-800-255-7778
R
XC18V00 Series In-System Programmable Configuration PROMs
Pinout and Pin Description
Table 1 provides a list of the pin names and descriptions for the 44-pin VQFP and PLCC and the 20-pin SOIC and PLCC
packages.
Table 1: Pin Names and Descriptions
Boundary
Scan
Order
20-pin
SOIC &
PLCC
Pin
Name
44-pin
VQFP
44-pin
PLCC
Function
Pin Description
D0
D1
D2
D3
D4
D5
D6
D7
CLK
4
3
DATA OUT D0 is the DATA output pin to provide data
40
29
42
27
9
2
1
for configuring an FPGA in serial mode.
OUTPUT
ENABLE
6
5
DATA OUT D0-D7 are the output pins to provide
parallel data for configuring a Xilinx
35
4
16
2
OUTPUT
ENABLE
FPGA in Slave-Parallel/SelectMap mode.
D1-D7 remain in HIGHZ state when the
PROM operates in serial mode.
2
1
DATA OUT
D1-D7 can be left unconnected when the
PROM is used in serial mode.
OUTPUT
ENABLE
8
7
DATA OUT
33
15
31
20
25
15
OUTPUT
ENABLE
(1)
24
23
DATA OUT
7
OUTPUT
ENABLE
10
9
DATA OUT
25
14
19
14
9
OUTPUT
ENABLE
17
16
DATA OUT
OUTPUT
ENABLE
14
13
DATA OUT
12
OUTPUT
ENABLE
0
DATA IN
Each rising edge on the CLK input
increments the internal address counter if
both CE is Low and OE/RESET is High.
43
13
5
3
8
OE/
RESET
20
19
18
DATA IN
When Low, this input holds the address
counter reset and the DATA output is in a
high-impedance state. This is a
19
DATA OUT
bidirectional open-drain pin that is held
Low while the PROM is reset. Polarity is
NOT programmable.
OUTPUT
ENABLE
CE
15
DATA IN
When CE is High, the device is put into
low-power standby mode, the address
counter is reset, and the DATA pins are
put in a high-impedance state.
15
21
10
2
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DS026 (v4.0) June 11, 2003
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Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
Table 1: Pin Names and Descriptions (Continued)
Boundary
20-pin
Pin
Name
Scan
Order
44-pin
VQFP
44-pin
PLCC
SOIC &
PLCC
Function
Pin Description
(1)
CF
22
21
DATA OUT Allows JTAG CONFIG instruction to
initiate FPGA configuration without
10
16
7
OUTPUT
powering down FPGA. This is an
ENABLE
open-drain output that is pulsed Low by
the JTAG CONFIG command.
CEO
12
11
DATA OUT Chip Enable Output (CEO) is connected
to the CE input of the next PROM in the
21
27
13
OUTPUT
chain. This output is Low when CE is Low
ENABLE
and OE/RESET input is High, AND the
internal address counter has been
incremented beyond its Terminal Count
(TC) value. CEO returns to High when
OE/RESET goes Low or CE goes High.
GND
TMS
GND is the ground connection.
6, 18, 28 &
41
3, 12, 24
& 34
11
5
MODE
SELECT
The state of TMS on the rising edge of
TCK determines the state transitions at
the Test Access Port (TAP) controller.
TMS has an internal 50K ohm resistive
pull-up on it to provide a logic “1” to the
device if the pin is not driven.
5
11
TCK
TDI
CLOCK
DATA IN
This pin is the JTAG test clock. It
sequences the TAP controller and all the
JTAG test and programming electronics.
7
3
13
9
6
4
This pin is the serial input to all JTAG
instruction and data registers. TDI has an
internal 50K ohm resistive pull-up on it to
provide a logic “1” to the system if the pin
is not driven.
TDO
DATA OUT This pin is the serial output for all JTAG
instruction and data registers. TDO has
an internal 50K ohm resistive pull-up on it
to provide a logic “1” to the system if the
pin is not driven.
31
37
17
(3)
V
Positive 3.3V supply voltage for internal
logic.
17, 35 &
38
23, 41 &
44
18 & 20
CCINT
(3)
(3)
V
Positive 3.3V or 2.5V supply voltage
connected to the input buffers and
8, 16, 26 & 14, 22, 32
19
CCO
(2)
36
& 42
output voltage drivers.
NC
No connects.
1, 2, 4,
1, 6, 7, 8,
11, 12, 20, 10,17, 18,
22, 23, 24, 26,28, 29,
30, 32, 33, 30,36, 38,
34, 37, 39, 39, 40, 43
44
Notes:
1. By default, pin 7 is the D4 pin in the 20-pin packages. However, CF --> D4 programming option can be set to override the default and route
the CF function to pin 7 in the Serial mode.
2. For devices with IDCODES 0502x093h, the input buffers are supplied by V
.
CCINT
3. For devices with IDCODES, 0503x093h, these V
pins are no connects: pin 38 in 44-pin VQFP package, pin 44 in 44-pin PLCC
CCINT
package and pin 20 in 20-pin SOIC and20-pin PLCC packages.
DS026 (v4.0) June 11, 2003
Product Specification
www.xilinx.com
1-800-255-7778
3
R
XC18V00 Series In-System Programmable Configuration PROMs
Pinout Diagrams
20
19
18
17
16
15
14
13
12
11
1
2
3
4
5
6
7
8
DATA(D0)
D2
VCCINT*
VCCO
VCCINT*
TDO
D1
D3
D5
CEO
D7
GND
CLK
TDI
TMS
TCK
SO20
Top
CF/D4*
OE/RESET
D6
View
NC
NC
TDI
7
8
9
NC
NC
TDO
NC
D1
39
38
37
36
35
34
33
32
31
30
29
9
10
CE
NC
10
11
12
13
14
15
16
17
TMS
GND
TCK
PC44
Top View
*See pin descriptions.
GND
D3
DS026_14_060403
V
V
CCO
D4
CF
NC
CCO
D5
NC
NC
18
17
16
15
14
VCCINT*
TDO
D1
D3
D5
TDI
TMS
TCK
4
5
6
7
8
PC20
Top View
*See pin descriptions.
D4/CF*
OE/RESET
DS026_12_060403
*See pin descriptions.
DS026_15_060403
NC
NC
TDI
1
2
3
4
5
6
7
8
NC
NC
TDO
NC
D1
33
32
31
30
29
28
27
26
25
24
23
NC
TMS
GND
TCK
VQ44
Top View
GND
D3
V
V
CCO
D4
CF
NC
CCO
9
10
11
D5
NC
NC
*See pin descriptions.
DS026_13_060403
4
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1-800-255-7778
DS026 (v4.0) June 11, 2003
Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
Xilinx FPGAs and Compatible PROMs
Table 2 provides a list of Xilinx FPGAs and compatible
PROMs.
Table 2: Xilinx FPGAs and Compatible PROMs
Configuration
Bits
XC18V00
Solution
Device
Table 2: Xilinx FPGAs and Compatible PROMs
XCV800
4,715,616
XC18V04 +
XC18V512
Configuration
Bits
XC18V00
Solution
Device
XC2VP2
XC2VP4
XC2VP7
XCV1000
6,127,744
XC18V04 +
XC18V02
1,305,440
3,006,560
4,485,472
XC18V02
XC18V04
XCV50E
XCV100E
XCV200E
XCV300E
XCV400E
XCV405E
XCV600E
XCV812E
XCV1000E
XCV1600E
XCV2000E
XCV2600E
XCV3200E
XC2S15
630,048
863,840
XC18V01
XC18V01
XC18V04 +
XC18V512
1,442,016
1,875,648
2,693,440
3,430,400
3,961,632
6,519,648
6,587,520
8,308,992
10,159,648
12,922,336
16,283,712
197,696
XC18V02
XC2VP20
XC2VP30
XC2VP40
XC2VP50
XC2VP70
8,214,624
11,364,608
15,563,264
19,021,472
25,604,096
2 of XC18V04
3 of XC18V04
4 of XC18V04
5 of XC18V04
XC18V02
XC18V04
XC18V04
XC18V04
6 of XC18V04 +
XC18V512
2 of XC18V04
2 of XC18V04
2 of XC18V04
3 of XC18V04
4 of XC18V04
4 of XC18V04
XC18V512
XC18V512
XC18V01
XC2VP100
XC2VP125
33,645,312
42,782,208
8 of XC18V04 +
XC18V512
10 of XC18V04 +
XC18V01
XC2V40
XC2V80
360,096
635,296
XC18V512
XC18V01
XC18V02
XC18V04
XC18V04
XC2V250
XC2V500
XC2V1000
XC2V1500
1,697,184
2,761,888
4,082,592
5,659,296
XC2S30
336,768
XC2S50
559,200
XC2S100
XC2S150
XC2S200
XC2S50E
XC2S100E
XC2S150E
XC2S200E
XC2S300E
XC2S400E
XC2S600E
XC3S50
781,216
XC18V01
XC18V04
+ XC18V02
1,040,096
1,335,840
630,048
XC18V01
XC2V2000
XC2V3000
XC2V4000
XC2V6000
7,492,000
10,494,368
15,659,936
21,849,504
2 of XC18V04
3 of XC18V04
4 of XC18V04
XC18V02
XC18V01
863,840
XC18V01
5 of XC18V04 +
XC18V02
1,134,496
1,442,016
1,875,648
2,693,440
3,961,632
439,264
XC18V02
XC18V02
XC2V8000
XCV50
29,063,072
559,200
7 of XC18V04
XC18V01
XC18V01
XC18V01
XC18V02
XC18V02
XC18V04
XC18V04
XC18V02
XC18V04
XCV100
XCV150
XCV200
XCV300
XCV400
XCV600
781,216
XC18V04
1,040,096
1,335,840
1,751,808
2,546,048
3,607,968
XC18V512
XC18V01
XC3S200
XC3S400
XC3S1000
1,047,616
1,699,136
3,223,488
XC18V02
XC18V04
DS026 (v4.0) June 11, 2003
Product Specification
www.xilinx.com
1-800-255-7778
5
R
XC18V00 Series In-System Programmable Configuration PROMs
Table 2: Xilinx FPGAs and Compatible PROMs
protocol as shown in Figure 2. In-system programming
offers quick and efficient design iterations and eliminates
unnecessary package handling or socketing of devices.
The Xilinx development system provides the programming
data sequence using either Xilinx iMPACT software and a
download cable, a third-party JTAG development system, a
JTAG-compatible board tester, or a simple microprocessor
interface that emulates the JTAG instruction sequence. The
iMPACT software also outputs serial vector format (SVF)
files for use with any tools that accept SVF format and with
automatic test equipment.
Configuration
Bits
XC18V00
Solution
Device
XC3S1500
5,214,784
XC18V04 +
XC18V01
XC3S2000
XC3S4000
XC3S5000
7,673,024
11,316,864
13,271,936
2 of XC18V04
3 of XC18V04
3 of XC18V04 +
XC18V01
All outputs are held in a high-impedance state or held at
clamp levels during in-system programming.
Capacity
OE/RESET
Devices
XC18V04
XC18V02
XC18V01
XC18V512
Configuration Bits
The ISP programming algorithm requires issuance of a
reset that causes OE to go Low.
4,194,304
2,097,152
1,048,576
524,288
External Programming
Xilinx reprogrammable PROMs can also be programmed by
the Xilinx HW-130, Xilinx MultiPRO, or a third-party device
programmer. This provides the added flexibility of using
pre-programmed devices with an in-system programmable
option for future enhancements and design changes.
In-System Programming
In-System Programmable PROMs can be programmed
individually, or two or more can be daisy-chained together
and programmed in-system via the standard 4-pin JTAG
(a)
(b)
DS026_02_06/1103
Figure 2: In-System Programming Operation (a) Solder Device to PCB and (b) Program Using Download Cable
Reliability and Endurance
Design Security
Xilinx in-system programmable products provide a guaran-
teed endurance level of 20,000 in-system program/erase
cycles and a minimum data retention of 20 years. Each
device meets all functional, performance, and data reten-
tion specifications within this endurance limit.
The Xilinx in-system programmable PROM devices incor-
porate advanced data security features to fully protect the
programming data against unauthorized reading via JTAG.
Table 3 shows the security setting available.
6
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DS026 (v4.0) June 11, 2003
Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
The read security bit can be set by the user to prevent the
internal programming pattern from being read or copied via
JTAG. When set, it allows device erase. Erasing the entire
device is the only way to reset the read security bit.
instruction scan sequence. In preparation for an instruction
scan sequence, the instruction register is parallel loaded
with a fixed instruction capture pattern. This pattern is
shifted out onto TDO (LSB first), while an instruction is
shifted into the instruction register from TDI. The detailed
composition of the instruction capture pattern is illustrated
in Figure 3.
Table 3: Data Security Options
Default = Reset
Set
The ISP Status field, IR(4), contains logic “1” if the device is
currently in ISP mode; otherwise, it contains logic “0”. The
Security field, IR(3), contains logic “1” if the device has been
programmed with the security option turned on; otherwise, it
contains logic “0”.
Read Allowed
Program/Erase Allowed
Verify Allowed
Read Inhibited via JTAG
Program/Erase Allowed
Verify Inhibited
IEEE 1149.1 Boundary-Scan (JTAG)
IR[7:5]
IR[4]
IR[3]
IR[2] IR[1:0]
0 1
The XC18V00 family is fully compliant with the IEEE Std.
1149.1 Boundary-Scan, also known as JTAG. A Test
Access Port (TAP) and registers are provided to support all
required boundary scan instructions, as well as many of the
optional instructions specified by IEEE Std. 1149.1. In addi-
tion, the JTAG interface is used to implement in-system pro-
gramming (ISP) to facilitate configuration, erasure, and
verification operations on the XC18V00 device.
TDI->
0 0 0
ISP
Security
0
->TDO
Status
Notes:
1. IR(1:0) = 01 is specified by IEEE Std. 1149.1
Figure 3: Instruction Register Values Loaded into IR as
Part of an Instruction Scan Sequence
Table 4 lists the required and optional boundary-scan
instructions supported in the XC18V00. Refer to the IEEE
Std. 1149.1 specification for a complete description of
boundary-scan architecture and the required and optional
instructions.
Boundary Scan Register
The boundary-scan register is used to control and observe
the state of the device pins during the EXTEST, SAM-
PLE/PRELOAD, and CLAMP instructions. Each output pin
on the XC18V00 has two register stages that contribute to
the boundary-scan register, while each input pin only has
one register stage.
Table 4: Boundary Scan Instructions
Boundary-Scan
Command
Binary
Code [7:0]
Description
For each output pin, the register stage nearest to TDI con-
trols and observes the output state, and the second stage
closest to TDO controls and observes the High-Z enable
state of the pin.
Required Instructions
BYPASS
11111111 Enables BYPASS
SAMPLE/
PRELOAD
00000001 Enables boundary-scan
SAMPLE/PRELOAD operation
For each input pin, the register stage controls and observes
the input state of the pin.
EXTEST
00000000 Enables boundary-scan
EXTEST operation
Identification Registers
Optional Instructions
The IDCODE is a fixed, vendor-assigned value that is used
to electrically identify the manufacturer and type of the
device being addressed. The IDCODE register is 32 bits
wide. The IDCODE register can be shifted out for examina-
tion by using the IDCODE instruction. The IDCODE is avail-
able to any other system component via JTAG.
CLAMP
11111010 Enables boundary-scan
CLAMP operation
HIGHZ
11111100 all outputs in high-impedance
state simultaneously
IDCODE
11111110 Enables shifting out
32-bit IDCODE
The IDCODE register has the following binary format:
vvvv:ffff:ffff:aaaa:aaaa:cccc:cccc:ccc1
where
USERCODE
11111101 Enables shifting out
32-bit USERCODE
XC18V00 Specific Instructions
v = the die version number
CONFIG
11101110 Initiates FPGA configuration
by pulsing CF pin Low once
f = the family code (50h for XC18V00 family)
a = the ISP PROM product ID (36h for the XC18V04)
c = the company code (49h for Xilinx)
Instruction Register
The Instruction Register (IR) for the XC18V00 is eight bits
wide and is connected between TDI and TDO during an
Note: The LSB of the IDCODE register is always read as
logic “1” as defined by IEEE Std. 1149.1.
DS026 (v4.0) June 11, 2003
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R
XC18V00 Series In-System Programmable Configuration PROMs
Table 5 lists the IDCODE register values for the XC18V00
devices.
the XC18V00 device. If the device is blank or was not
loaded during programming, the USERCODE register con-
tains FFFFFFFFh.
Table 5: IDCODES Assigned to XC18V00 Devices
XC18V00 TAP Characteristics
ISP-PROM
XC18V01
XC18V02
XC18V04
XC18V512
IDCODE
The XC18V00 family performs both in-system programming
and IEEE 1149.1 boundary-scan (JTAG) testing via a single
4-wire Test Access Port (TAP). This simplifies system
designs and allows standard Automatic Test Equipment to
perform both functions. The AC characteristics of the
XC18V00 TAP are described as follows.
05024093h or 05034093h
05025093h or 05035093h
05026093h or 05036093h
05023093h or 05033093h
TAP Timing
Figure 4 shows the timing relationships of the TAP signals.
These TAP timing characteristics are identical for both
boundary-scan and ISP operations.
The USERCODE instruction gives access to a 32-bit user
programmable scratch pad typically used to supply informa-
tion about the device’s programmed contents. By using the
USERCODE instruction, a user-programmable identifica-
tion code can be shifted out for examination. This code is
loaded into the USERCODE register during programming of
T
CKMIN1,2
TCK
TMS
T
T
MSS
MSH
T
T
DIH
DIS
TDI
T
DOV
TDO
DS026_04_032702
Figure 4: Test Access Port Timing
TAP AC Parameters
Table 6 shows the timing parameters for the TAP waveforms shown in Figure 4.
Table 6: Test Access Port Timing Parameters
Symbol
Parameter
TCK minimum clock period
Min
100
50
10
25
10
25
-
Max
Units
T
-
-
ns
ns
ns
ns
ns
ns
ns
CKMIN1
CKMIN2
T
TCK minimum clock period, Bypass Mode
TMS setup time
T
T
-
MSS
TMS hold time
-
MSH
T
TDI setup time
-
DIS
T
TDI hold time
-
DIH
T
TDO valid delay
25
DOV
8
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Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
Connecting Configuration PROMs
Connecting the FPGA device with the configuration PROM
(see Figure 5 and Figure 6).
through a user control register in the XC18V00 device. This
control register is accessible through JTAG, and is set using
the “Parallel mode” setting on the Xilinx iMPACT software.
Serial output is the default configuration mode.
•
The DATA output(s) of the PROM(s) drives the D
input of the lead FPGA device.
IN
•
The Master FPGA CCLK output drives the CLK input(s)
of the PROM(s) (in Master-Serial and
Master Serial Mode Summary
The I/O and logic functions of the Configurable Logic Block
(CLB) and their associated interconnections are estab-
lished by a configuration program. The program is loaded
either automatically upon power up, or on command,
depending on the state of the three FPGA mode pins. In
Master Serial mode, the FPGA automatically loads the con-
figuration program from an external memory. Xilinx PROMs
are designed to accommodate the Master Serial mode.
Master-SelectMAP modes only).
•
•
The CEO output of a PROM drives the CE input of the
next PROM in a daisy chain (if any).
The OE/RESET pins of all PROMs are connected to
the INIT pins of all FPGA devices. This connection
assures that the PROM address counter is reset before
the start of any (re)configuration, even when a
reconfiguration is initiated by a V
glitch.
CCINT
Upon power-up or reconfiguration, an FPGA enters the Mas-
ter Serial mode whenever all three of the FPGA mode-select
pins are Low (M0=0, M1=0, M2=0). Data is read from the
PROM sequentially on a single data line. Synchronization is
provided by the rising edge of the temporary signal CCLK,
which is generated by the FPGA during configuration.
•
•
The PROM CE input can be driven from the DONE pin.
The CE input of the first (or only) PROM can be driven
by the DONE output of all target FPGA devices,
provided that DONE is not permanently grounded. CE
can also be permanently tied Low, but this keeps the
DATA output active and causes an unnecessary supply
current of 10 mA maximum.
Master Serial Mode provides a simple configuration inter-
face. Only a serial data line, a clock line, and two control
lines are required to configure an FPGA. Data from the
PROM is read sequentially, accessed via the internal
address and bit counters which are incremented on every
valid rising edge of CCLK. If the user-programmable,
Slave-Parallel/SelectMap mode is similar to slave serial
mode. The DATA is clocked out of the PROM one byte
per CCLK instead of one bit per CCLK cycle. See FPGA
data sheets for special configuration requirements.
dual-function D pin on the FPGA is used only for configu-
IN
Initiating FPGA Configuration
ration, it must still be held at a defined level during normal
operation. The Xilinx FPGA families take care of this auto-
matically with an on-chip pull-up resistor.
The XC18V00 devices incorporate a pin named CF that is
controllable through the JTAG CONFIG instruction. Execut-
ing the CONFIG instruction through JTAG pulses the CF
low once for 300-500 ns, which resets the FPGA and ini-
tiates configuration.
Cascading Configuration PROMs
For multiple FPGAs configured as a serial daisy-chain, or a
single FPGA requiring larger configuration memories in a
serial or SelectMAP configuration mode, cascaded PROMs
provide additional memory (Figure 5). Multiple XC18V00
devices can be concatenated by using the CEO output to
drive the CE input of the downstream device. The clock
inputs and the data outputs of all XC18V00 devices in the
chain are interconnected. After the last data from the first
PROM is read, the next clock signal to the PROM asserts its
CEO output Low and drives its DATA line to a high-imped-
ance state. The second PROM recognizes the Low level on
its CE input and enables its DATA output. See Figure 7.
The CF pin must be connected to the PROGRAM pin on the
FPGA(s) to use this feature.
The iMPACT software can also issue a JTAG CONFIG
command to initiate FPGA configuration through the “Load
FPGA” setting.
The 20-pin packages do not have a dedicated CF pin. For
20-pin packages, the CF --> D4 setting can be used to route
the CF pin function to pin 7 only if the parallel output mode
is not used.
Selecting Configuration Modes
The XC18V00 accommodates serial and parallel methods
of configuration. The configuration modes are selectable
After configuration is complete, address counters of all cas-
caded PROMs are reset if the PROM OE/RESET pin goes
Low or CE goes High.
DS026 (v4.0) June 11, 2003
Product Specification
www.xilinx.com
1-800-255-7778
9
R
XC18V00 Series In-System Programmable Configuration PROMs
VCCO
(See Note 2)
VCCO VCCINT
(See Note 2)
VCCO VCCINT
(See Note 2)
4.7K
MODE PINS
(See Note 1)
MODE PINS
(See Note 1)
DIN
DIN
DOUT
VCCINT
VCCO
D0
VCCINT
VCCO
D0
Xilinx
FPGA
Xilinx
FPGA
XC18V00
XC18V00
VCCO
(See
4.7K
Master
Serial
Slave
Serial
Cascaded
PROM
First
PROM
Note
1)
J1
1
TDI
CLK
CE
TDI
CLK
CE
CCLK
DONE
CCLK
TDI
2
3
4
TMS
TMS
TMS
DONE
TCK
CEO
TCK
CEO
TCK
TDO
OE/RESET
CF
OE/RESET
CF
INIT
INIT
PROGRAM
PROGRAM
TDI
TDI
TDO
TDO
GND
GND
TMS
TCK
TMS
TCK
TDO
TDO
Notes:
1
2
For Mode pin connections and DONE pin pullup value, refer to appropriate FPGA data sheet.
For compatible voltages, refer to the appropriate FPGA data sheet.
DS026_08_061003
Figure 5: Configuring Multiple Devices in Master/Slave Serial Mode
(2)
VCCO
(2)
VCCINT
(2)
VCCINT
VCCO
VCCO
4.7K
(1)
MODE PINS
MODE PINS
**D[0:7]
(3)
D[0:7]
(3)
(3)
D[0:7]
VCCINT
VCCO
D[0:7]
VCCINT
VCCO
Xilinx
Virtex-II
FPGA
Xilinx
Virtex-II
FPGA
(2)
VCCO
XC18V00
XC18V00
4.7K
Master
Serial/
SelectMAP
Slave
Serial/
SelectMAP
Cascaded
PROM
First
PROM
(1)
J1
1
TDI
CLK
CE
TDI
CLK
CCLK
CCLK
TDI
2
3
4
TMS
TMS
TMS
CE
DONE
DONE
TCK
CEO
TCK
CEO
TCK
TDO
OE/RESET
CF
OE/RESET
CF
INIT
INIT
PROGRAM
PROGRAM
TDI
TDI
TDO
TDO
GND
GND
TMS
TCK
TMS
TCK
TDO
TDO
Notes:
1
2
3
For Mode pin connections and DONE pin pullup value, refer to the appropriate FPGA data sheet.
For compatible voltges, refer to the appropriate FPGA data sheet.
Master/Slave Serial Mode does not require D[1:7] to be connected.
DS026_09_051003
Figure 6: Configuring Multiple Virtex-II Devices with Identical Patterns in Master/Slave or Serial/SelectMAP Modes
10
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DS026 (v4.0) June 11, 2003
1-800-255-7778
Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
OPTIONAL
Daisy-chained
FPGAs with
different
DOUT
configurations
FPGA
(2)
Vcco
OPTIONAL
Slave FPGAs
with identical
4.7K
(1)
configurations
Modes
(2)
(2)
VCCO
VCCINT
(2)
Vcco
VCCINT VCCO
(2)
Vcco
4.7K
VCCO
VCCINT
DATA
VCCINT VCCO
DATA
DIN
First
PROM
Cascaded
PROM
CCLK
CLK
CE
CLK
CE
CEO
DONE
INIT
OE/RESET
CF
OE/RESET
CF
PROGRAM
Notes:
1
2
For Mode pin connections and Done pullup value, refer to the appropriate FPGA data sheet.
For compatible voltages, refer to the appropriate FPGA data sheet.
(a) Master Serial Mode
(1)
(1)
I/O
I/O
(4)
VCCINT VCCO
(4)
External
Osc
VCCINT VCCO
(3)
CS
WRITE
(2)
Modes
1K
Vcco
1K
VIRTEX
Select MAP
(4)
Vcco
VCCINT VCCO
VCCINT VCCO
(4)
(4)
Vcco
NC
BUSY
4.7K
XC18Vxx
XC18Vxx
(2)
4.7K
CLK
CLK
CCLK
D[0:7]
DONE
INIT
8
PROGRAM
CEO
CF
CEO
CF
D[0:7]
CE
D[0:7]
CE
OE/RESET
OE/RESET
Notes:
1
2
3
4
CS and WRITE must be either driven Low or pulled down externally. One option is shown.
For Mode pin connections and Done pullup value, refer to the appropriate FPGA data sheet.
External oscillator required for Virtex/Virtex-E SelectMAP or Virtex-II/Virtex-II Pro Slave-SelectMAP modes.
For compatible voltages, refer to the appropriate FPGA data sheet.
(b) Virtex/Virtex-E/Virtex-II/Virtex-II Pro SelectMAP Mode
(1)
I/O
(4)
(1)
External
Osc
VCCINT VCCO
I/O
1K
Vcco
(3)
CS
(2)
Modes
WRITE
1K
Spartan-II,
Spartan-IIE
(4)
Vcco
VCCINT VCCO
(4)
VCCINT
(4)
NC
BUSY
3.3K
XC18Vxx
(2)
4.7K
CLK
CCLK
D[0:7]
DONE
INIT
8
PROGRAM
D[0:7]
CE
CF
OE/RESET
Notes:
1
2
CS and WRITE must be pulled down to be used as I/O. One option is shown.
For Mode pin connections and Done pullup value and if Drive Done configuration option is not active, refer to
the appropriate FPGA data sheet.
3
External oscillator required for Spartan-II/Spartan-IIE Slave-Parallel modes.
4 For compatible voltages, refer to the appropriate FPGA data sheet.
(c) Spartan-II/Spartan-IIE Slave-Parallel Mode
DS026_05_060403
Figure 7: (a) Master Serial Mode (b) Virtex/Virtex-E/Virtex-II Pro SelectMAP Mode (c) Spartan-II/Spartan-IIE
Slave-Parallel Mode (dotted lines indicate optional connection)
DS026 (v4.0) June 11, 2003
www.xilinx.com
11
Product Specification
1-800-255-7778
R
XC18V00 Series In-System Programmable Configuration PROMs
Reset Activation
On power up, OE/RESET is held low until the XC18V00 is
active (1 ms). OE/RESET is connected to an external resis-
tor to pull OE/RESET HIGH releasing the FPGA INIT and
allowing configuration to begin. If the power drops below
2.0V, the PROM resets. OE/RESET polarity is not program-
mable. See Figure 8 for power-up requirements.
remains in a high-impedance state regardless of the state of
the OE input. JTAG pins TMS, TDI and TDO can be in a
high-impedance state or High. See Table 7.
5V Tolerant I/Os
The I/Os on each re-programmable PROM are fully 5V tol-
erant even through the core power supply is 3.3V. This
allows 5V CMOS signals to connect directly to the PROM
inputs without damage. In addition, the 3.3V V
supply can be applied before or after 5V signals are applied
to the I/Os. In mixed 5V/3.3V/2.5V systems, the user pins,
power
3.6V
CCINT
Recommended Operating Range
3.0V
Recommended
the core power supply (V
), and the output power sup-
CCINT
ply (V
) can have power applied in any order. This
Rise
VCCINT
Time
CCO
makes the PROM devices immune to power supply
sequencing issues.
Customer Control Bits
0V
0ms 1ms
50ms
The XC18V00 PROMs have various control bits accessible
by the customer. These can be set after the array has been
programmed using “Skip User Array” in Xilinx iMPACT soft-
ware. The iMPACT software can set these bits to enable the
optional JTAG read security, parallel configuration mode, or
CF-->D4 pin function. See Table 7.
Time (ms)
ds026_10_061103
Figure 8: V
Power-Up Requirements
CCINT
Standby Mode
The PROM enters a low-power standby mode whenever
CE is asserted High. The address is reset. The output
Table 7: Truth Table for PROM Control Inputs
Control Inputs
Outputs
OE/RESET
CE
Internal Address
DATA
CEO
I
CC
(1)
High
Low
If address < TC : increment
Active
High-Z
High
Low
Active
Reduced
(1)
If address > TC : don’t change
Low
High
Low
Low
High
High
Held reset
Held reset
Held reset
High-Z
High-Z
High-Z
High
High
High
Active
Standby
Standby
Notes:
1. TC = Terminal Count = highest address value. TC + 1 = address 0.
12
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1-800-255-7778
DS026 (v4.0) June 11, 2003
Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
Absolute Maximum Ratings(1,2)
Symbol
Description
Supply voltage relative to GND
Value
–0.5 to +4.0
–0.5 to +5.5
–0.5 to +5.5
–65 to +150
+220
Units
V
V
V
CCINT/ CCO
V
Input voltage with respect to GND
Voltage applied to High-Z output
Storage temperature (ambient)
Maximum soldering temperature (10s @ 1/16 in.)
Junction temperature
V
IN
V
V
TS
T
T
°C
°C
°C
STG
SOL
T
+125
J
Notes:
1. Maximum DC undershoot below GND must be limited to either 0.5V or 10 mA, whichever is easier to achieve. During transitions, the
device pins can undershoot to –2.0V or overshoot to +7.0V, provided this over- or undershoot lasts less then 10 ns and with the
forcing current being limited to 200 mA.
2. Stresses beyond those listed under Absolute Maximum Ratings might cause permanent damage to the device. These are stress
ratings only, and functional operation of the device at these or any other conditions beyond those listed under Operating Conditions
is not implied. Exposure to Absolute Maximum Ratings conditions for extended periods of time might affect device reliability.
Recommended Operating Conditions
Symbol
Parameter
Min
3.0
3.0
2.3
0
Max
3.6
3.6
2.7
0.8
5.5
Units
V
V
Internal voltage supply
CCINT
V
Supply voltage for output drivers for 3.3V operation
Supply voltage for output drivers for 2.5V operation
Low-level input voltage
V
CCO
V
V
V
IL
V
High-level input voltage
2.0
0
V
IH
V
Output voltage
V
V
O
CCO
(1)
T
V
rise time from 0V to nominal voltage
CCINT
1
50
ms
C
VCC
T
Operating ambient temperature
–40°
85°
A
Notes:
1. At power up, the device requires the V
power supply to monotonically rise from 0V to nominal voltage within the specified
CCINT
V
rise time. If the power supply cannot meet this requirement, then the device might not perform power-on-reset properly. See
CCINT
Figure 8.
Quality and Reliability Characteristics
Symbol
Description
Min
20
Max
Units
Years
Cycles
Volts
T
Data retention
-
-
-
DR
N
Program/erase cycles (Endurance)
Electrostatic discharge (ESD)
20,000
2,000
PE
V
ESD
DS026 (v4.0) June 11, 2003
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13
Product Specification
1-800-255-7778
R
XC18V00 Series In-System Programmable Configuration PROMs
DC Characteristics Over Operating Conditions
Symbol
Parameter
Test Conditions
Min
2.4
Max
-
Units
V
V
High-level output voltage for 3.3V outputs
High-level output voltage for 2.5V outputs
Low-level output voltage for 3.3V outputs
Low-level output voltage for 2.5V outputs
Supply current, active mode
I
I
I
I
= –4 mA
= –500 µA
= 8 mA
OH
OH
OH
OL
OL
90% V
-
V
CCO
V
-
-
-
-
-
0.4
0.4
25
10
100
V
OL
CC
= 500 µA
V
I
25 MHz
mA
mA
µA
I
Supply current, standby mode
CCS
I
JTAG pins TMS, TDI, and TDO pull-up
current
V
V
MAX
CCINT =
ILJ
= GND
IN
I
Input leakage current
V
V
V
= Max
= GND or
–10
–10
10
10
µA
µA
IL
CCINT
IN
CCINT
I
Input and output High-Z leakage current
V
V
V
= Max
= GND or
IH
CCINT
IN
CCINT
C
Input capacitance
Output capacitance
V
= GND
IN
-
-
8
pF
pF
IN
f = 1.0 MHz
C
V
= GND
14
OUT
OUT
f = 1.0 MHz
Notes:
1. Internal pull-up resistors guarantee valid logic levels at unconnected input pins. These pull-up resistors do not guarantee valid logic
levels when input pins are connected to other circuits.
14
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DS026 (v4.0) June 11, 2003
1-800-255-7778
Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
AC Characteristics Over Operating Conditions for XC18V04 and XC18V02
CE
T
T
SCE
HCE
OE/RESET
CLK
T
HOE
T
T
HC
LC
T
CYC
T
T
DF
OE
T
T
CAC
OH
T
CE
DATA
T
OH
DS026_06_012000
Symbol
Description
Min
-
Max
Units
T
T
OE/RESET to data delay
CE to data delay
10
20
20
-
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
OE
CE
-
T
CLK to data delay
-
CAC
T
Data hold from CE, OE/RESET, or CLK
0
OH
(2)
T
CE or OE/RESET to data float delay
-
25
-
DF
T
Clock periods
50
10
10
25
250
250
CYC
(3)
T
CLK Low time
-
LC
HC
(3)
T
CLK High time
-
(3)
T
T
CE setup time to CLK (guarantees proper counting)
CE High time (guarantees counters are reset)
-
SCE
HCE
HOE
-
T
OE/RESET hold time (guarantees counters are reset)
-
Notes:
1. AC test load = 50 pF.
2. Float delays are measured with 5 pF AC loads. Transition is measured at 200 mV from steady state active levels.
3. Guaranteed by design, not tested.
4. All AC parameters are measured with V = 0.0V and V = 3.0V.
IL
IH
5. If T
6. If T
High < 2 µs, T = 2 µs.
HCE
HCE
CE
Low < 2 µs, T = 2 µs.
OE
DS026 (v4.0) June 11, 2003
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15
Product Specification
1-800-255-7778
R
XC18V00 Series In-System Programmable Configuration PROMs
AC Characteristics Over Operating Conditions for XC18V01 and XC18V512
CE
T
T
SCE
HCE
OE/RESET
CLK
T
HOE
T
T
HC
LC
T
CYC
T
T
DF
OE
T
T
CAC
OH
T
CE
DATA
T
OH
DS026_06_012000
Symbol
Description
Min
-
Max
Units
T
T
OE/RESET to data delay
CE to data delay
10
15
15
-
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
OE
CE
-
T
CLK to data delay
-
CAC
T
Data hold from CE, OE/RESET, or CLK
0
OH
(2)
T
CE or OE/RESET to data float delay
-
25
-
DF
T
Clock periods
30
10
10
20
250
250
CYC
(3)
T
CLK Low time
-
LC
HC
(3)
T
CLK High time
-
(3)
T
T
CE setup time to CLK (guarantees proper counting)
CE High time (guarantees counters are reset)
-
SCE
HCE
HOE
-
T
OE/RESET hold time (guarantees counters are reset)
-
Notes:
1. AC test load = 50 pF.
2. Float delays are measured with 5 pF AC loads. Transition is measured at 200 mV from steady state active levels.
3. Guaranteed by design, not tested.
4. All AC parameters are measured with V = 0.0V and V = 3.0V.
IL
IH
5. If T
6. If T
High < 2 µs, T = 2 µs.
HCE
HOE
CE
High < 2 µs, T = 2 µs.
OE
16
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DS026 (v4.0) June 11, 2003
1-800-255-7778
Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
AC Characteristics Over Operating Conditions When Cascading for XC18V04 and
XC18V02
OE/RESET
CE
CLK
T
CDF
T
T
OCE
Last Bit
First Bit
DATA
CEO
T
OCK
OOE
DS026_07_020300
Symbol
Description
Min
Max
25
Units
ns
(2,3)
T
CLK to data float delay
-
-
-
-
CDF
OCK
OCE
OOE
(3)
T
T
CLK to CEO delay
20
ns
(3)
CE to CEO delay
20
ns
(3)
T
OE/RESET to CEO delay
20
ns
Notes:
1. AC test load = 50 pF.
2. Float delays are measured with 5 pF AC loads. Transition is measured at 200 mV from steady state active levels.
3. Guaranteed by design, not tested.
4. All AC parameters are measured with V = 0.0V and V = 3.0V.
IL
IH
DS026 (v4.0) June 11, 2003
www.xilinx.com
17
Product Specification
1-800-255-7778
R
XC18V00 Series In-System Programmable Configuration PROMs
AC Characteristics Over Operating Conditions When Cascading for XC18V01 and
XC18V512
OE/RESET
CE
CLK
T
CDF
T
T
OCE
Last Bit
First Bit
DATA
CEO
T
OCK
OOE
DS026_07_020300
Symbol
Description
Min
Max
25
Units
ns
(2,3)
T
CLK to data float delay
-
-
-
-
CDF
OCK
OCE
OOE
(3)
T
T
CLK to CEO delay
20
ns
(3)
CE to CEO delay
20
ns
(3)
T
OE/RESET to CEO delay
20
ns
Notes:
1. AC test load = 50 pF.
2. Float delays are measured with 5 pF AC loads. Transition is measured at 200 mV from steady state active levels.
3. Guaranteed by design, not tested.
4. All AC parameters are measured with V = 0.0V and V = 3.0V.
IL
IH
18
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DS026 (v4.0) June 11, 2003
1-800-255-7778
Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
Ordering Information
XC18V04 VQ44 C
Device Number
Operating Range/Processing
XC18V04
C = (T = –40°C to +85°C)
A
Package Type
XC18V02
XC18V01
XC18V512
VQ44 = 44-pin Plastic Quad Flat Package
PC44 = 44-pin Plastic Chip Carrier
SO20 = 20-pin Small-Outline Package
PC20 = 20-pin Plastic Leaded Chip Carrier
(1)
(2)
(2)
Notes:
1. XC18V04 and XC18V02 only.
2. XC18V01 and XC18V512 only.
Valid Ordering Combinations
XC18V04VQ44C
XC18V04PC44C
XC18V02VQ44C
XC18V02PC44C
XC18V01VQ44C
XC18V01PC20C
XC18V01SO20C
XC18V512VQ44C
XC18V512PC20C
XC18V512SO20C
Marking Information
44-pin Package
XC18V04 VQ44
Device Number
Operating Range/Processing
XC18V04
C = (T = –40°C to +85°C)
A
Package Type
XC18V02
XC18V01
XC18V512
VQ44 = 44-pin Plastic Quad Flat Package
PC44 = 44-pin Plastic Leaded Chip Carrier
(1)
Notes:
1. XC18V02 and XC18V04 only.
(1)
20-pin Package
Due to the small size of the serial PROM packages, the complete ordering part number cannot be marked on the
package. The XC prefix is deleted and the package code is simplified. Device marking is as follows:
18V01 S C
Device Number
Operating Range/Processing
18V01
18V512
C = (T = –40°C to +85°C)
A
Package Type
S = 20-pin Small-Outline Package
J = 20-pin Plastic Leaded Chip Carrier
Notes:
1. XC18V01 and XC18V512 only.
DS026 (v4.0) June 11, 2003
Product Specification
www.xilinx.com
1-800-255-7778
19
R
XC18V00 Series In-System Programmable Configuration PROMs
Revision History
The following table shows the revision history for this document.
Date
2/9/99
8/23/99
9/1/99
9/16/99
Version
1.0
Revision
First publication of this early access specification
Edited text, changed marking, added CF and parallel load
Corrected JTAG order, Security and Endurance data.
1.1
1.2
1.3
Corrected SelectMAP diagram, control inputs, reset polarity. Added JTAG and CF
description, 256 Kbit and 128 Kbit devices.
01/20/00
02/18/00
04/04/00
2.0
2.1
2.2
Added Q44 Package, changed XC18xx to XC18Vxx
Updated JTAG configuration, AC and DC characteristics
Removed stand alone resistor on INIT pin in Figure 5. Added Virtex-E and EM parts to
FPGA table.
06/29/00
11/13/00
2.3
2.4
Removed XC18V128 and updated format. Added AC characteristics for XC18V01,
XC18V512, and XC18V256 densities.
Features: changed 264 MHz to 264 Mb/s at 33 MHz; AC Spec.: T
units to ns, T
HCE
SCE
CE High time units to µs. Removed Standby Mode statement: “The lower power standby
modes available on some XC18V00 devices are set by the user in the programming
software”. Changed 10,000 cycles endurance to 20,000 cycles.
01/15/01
04/04/01
04/30/01
2.5
2.6
2.7
Updated Figures 5 and 6, added 4.7 resistors. Identification registers: changes ISP
PROM product ID from 06h to 26h.
Updated Figure 6, Virtex SelectMAP mode; added XC2V products to Compatible PROM
table; changed Endurance from 10,000 cycles, 10 years to 20,000, 20 years;
Updated Figure 6: removed Virtex-E in Note 2, fixed SelectMAP mode connections.
Under AC Characteristics Over Operating Conditions for XC18V04 and XC18V02,
changed T
from 25 ms to 25 ns.
SCE
06/11/01
09/28/01
2.8
2.9
AC Characteristics Over Operating Conditions for XC18V01 and XC18V512.
Changed Min values for T from 20 ms to 20 ns and for T from 2 ms to 2 µs.
SCE
HCE
Changed the boundary scan order for the CEO pin in Table 1, updated the configuration
bits values in the table under Xilinx FPGAs and Compatible PROMs, and added
information to the Recommended Operating Conditions table.
11/12/01
12/06/01
02/27/02
03/15/02
03/27/02
06/14/02
07/24/02
09/06/02
3.0
3.1
3.2
3.3
3.4
3.5
3.6
3.7
Updated for Spartan-IIE FPGA family.
Changed Figure 7(c).
Updated Table 2 and Figure 6 for the Virtex-II Pro family of devices.
Updated Xilinx software and modified Figure 6 and Figure 7.
Made changes to pages 1-3, 5, 7-11, 13, 14, and 18. Added new Figure 8 and Figure 9.
Made additions and changes to Table 2.
Changed last bullet under Connecting Configuration PROMs, page 9.
Multiple minor changes throughout, plus the addition of Pinout Diagrams, page 4 and
the deletion of Figure 9.
10/31/02
3.8
Made minor change on Figure 7 (b) and changed orientation of SO20 diagram on page 5.
20
www.xilinx.com
DS026 (v4.0) June 11, 2003
1-800-255-7778
Product Specification
R
XC18V00 Series In-System Programmable Configuration PROMs
11/18/02
04/17/03
06/11/03
3.9
3.10
4.0
Added XC2S400E and XC2S600E to Table 2.
Changes to Description, External Programming, and Table 2.
Added alternate IDCODES to Table 5, discontinued XC18V256 density, eliminated
industrial ordering combinations, extended commercial temperature range, and added
MultiPRO Desktop Tool support. Changed T
and T
to 250 ns in the tables on
HOE
HCE
page 15 and page 16. Made change in capacitance values DC Characteristics Over
Operating Conditions. Added Note 3 to Table 1. Other minor edits.
DS026 (v4.0) June 11, 2003
www.xilinx.com
21
Product Specification
1-800-255-7778
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